JP2016143015A - Projector and control method of projector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a projector including a projection lens, in which adjustment relating to picture qualities responding to the position of the projection lens can be easily performed.SOLUTION: The projector includes a light source part 21, a light modulation device 22, and a projection optical system 23 having a projection lens. The projector further includes a lens adjusting part 30 for adjusting the position of the projection lens, an input part 12 for receiving an input of the position of the projection lens and settings relating to the formation of image light, a storage 11 for storing the input position of the projection lens and input settings relating to the formation of image light, and a control part 10. The control part 10 controls the input part 12 to receive an input for selecting a position of the projection lens stored in the storage 11, and controls the lens adjusting part 30 to adjust the position of the projection lens responding to the position of the projection lens selected in accordance with the received input. The control part 10 controls the light modulation device 22 in accordance with the settings relating to the formation of image light responding to the selected position of the projection lens.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a projector and a projector control method.

  In general, in a projector provided with a projection lens, zoom and focus can be adjusted by adjusting the position of the projection lens. In addition, a projector that includes an anamorphic lens as a projection lens and can adjust the aspect ratio is also known (see, for example, Patent Document 1). The projector described in Patent Document 1 adjusts the position of the projection lens in accordance with the aspect ratio of the image signal.

JP 2012-194226 A

By the way, when the position of the projection lens is changed, the state of pixel shift or color unevenness may change due to the influence of chromatic aberration or the like of the lens. For this reason, after changing the position of the projection lens, it is necessary to make adjustments related to image quality such as pixel shift and color unevenness.
The present invention has been made in view of the above-described circumstances, and an object of the present invention is to make it possible to easily adjust an image quality corresponding to a position of a projection lens in a projector including a projection lens.

In order to achieve the above object, a projector of the present invention includes a light source, a modulation unit that modulates light emitted from the light source into image light based on an image signal, a projection lens that projects the image light, and the projection lens. An adjustment unit that adjusts the position of the projection lens, an input unit that receives an input of a setting relating to the formation of the image light by the modulation unit, and a position of the projection lens that is input by the input unit A storage unit that stores settings relating to the formation of the image light, a selection reception unit that receives an input for selecting the position of the projection lens stored in the storage unit, and a selection that is selected according to the input received by the selection reception unit. The adjustment unit adjusts the position of the projection lens in accordance with the position of the projection lens, and is related to the formation of the image light corresponding to the selected position of the projection lens. Characterized in that it comprises a an adjustment controller for controlling the modulation unit according to the setting.
According to the present invention, when adjusting the position of the projection lens, the image light can be adjusted corresponding to the position of the projection lens. For this reason, for example, the image quality, the aspect ratio, and the like can be adapted to the position of the projection lens, so that adjustment relating to the image quality corresponding to the position of the projection lens can be easily performed.

In the projector according to the aspect of the invention, the storage unit may include a position of the projection lens and a setting relating to the formation of the image light input by the input unit in association with the position of the projection lens. It memorizes.
According to the present invention, the setting contents corresponding to the position of the projection lens can be easily input and set for the setting relating to the formation of the image light.

Further, the present invention is the projector described above, wherein the storage unit stores the position of the projection lens and the setting relating to the formation of the image light in association with each other.
According to the present invention, it is possible to easily realize the setting relating to the formation of image light according to the position of the projection lens. Thereby, the adjustment regarding the image quality corresponding to the position of the projection lens can be easily performed.

Further, the present invention is the projector, wherein the input unit is configured to be able to input a plurality of setting items related to the formation of the image light by the modulation unit, and the setting items input by the input unit are It can be selected.
According to the present invention, it is possible to set arbitrary items regarding the formation of image light.

The present invention is the above projector, wherein the modulation unit forms an image based on the image signal, and modulates light emitted from the light source by the formed image, and the image by the modulation unit The settings relating to the formation of light include the aspect ratio of the image formed by the modulation unit, the alignment adjustment value for adjusting the formation position of the image, the color unevenness adjustment value of the image formed by the modulation unit, and the modulation unit One of the image quality setting values of the image is included.
According to the present invention, the image aspect ratio, alignment adjustment value, color unevenness adjustment value, image quality setting value, and the like can be appropriately adjusted in accordance with the position of the projection lens.

  In the projector, the adjustment unit may perform at least one of zoom adjustment by the projection lens and shift adjustment of the projection lens.

In order to achieve the above object, the present invention provides a projector control method for projecting image light by modulating light emitted from a light source into image light based on an image signal, and a position of a projection lens, and Accepts input of settings relating to the formation of the image light, stores the input position of the projection lens and the settings relating to the formation of the image light, and accepts and accepts input for selecting the stored position of the projection lens Adjusting the position of the projection lens according to the position of the projection lens selected according to the input, and forming the image light according to the setting relating to the formation of the image light corresponding to the position of the projection lens selected. Is controlled.
According to the present invention, when adjusting the position of the projection lens, the image light can be adjusted corresponding to the position of the projection lens. For this reason, for example, the image quality, the aspect ratio, and the like can be adapted to the position of the projection lens, so that adjustment relating to the image quality corresponding to the position of the projection lens can be easily performed.

FIG. 2 is a functional block diagram of the projector according to the embodiment. Explanatory drawing of operation | movement of a projector. The figure which shows the structural example of the setting value table regarding a lens position and image adjustment. The flowchart which shows operation | movement of a projector. The flowchart which shows operation | movement of a projector. The flowchart which shows operation | movement of a projector.

Embodiments to which the present invention is applied will be described below with reference to the drawings.
FIG. 1 is a block diagram illustrating a functional configuration of a projector 1 according to the embodiment. The projector 1 that projects an image on a screen SC as a projection surface projects an image on the screen SC based on image data D1 input from an external image supply device (not shown) such as a personal computer or various image players. .

  The image data D1 input to the projector 1 may be moving image (video) data or still image data. The projector 1 may project a video on the screen SC or display a still image on the screen SC. It is also possible to continue projecting. In the present embodiment, a configuration in which image data D1 that is digital image data is input to the projector 1 will be described. The projector 1 may be configured to A / D convert an analog image signal input from the outside and project an image based on the analog image signal.

The projector 1 includes a projection unit 20 that forms an optical image and an image processing system that electrically processes an image signal input to the projection unit 20, and these units operate according to the control of the control unit 10. To do.
The projection unit 20 includes a light source unit 21 (light source), a light modulation device 22 (modulation unit), and a projection optical system 23. The light source unit 21 includes a light source such as a xenon lamp, an ultra-high pressure mercury lamp, an LED (Light Emitting Diode), or a laser light source. The light source unit 21 includes a reflector and an auxiliary reflector for guiding the light from the light source to the light modulation device 22, a dimming element (not shown) for dimming the light from the light source on the path to the light modulation device 22, and the like. You may prepare. The light source drive unit 18 is connected to the light source unit 21. The light source driving unit 18 controls power supply to the light source unit 21 according to control of the control unit 10 described later, and turns on and off the light source of the light source unit 21.

  The light modulation device 22 receives a signal from an image processing system, which will be described later, and modulates the light emitted from the light source unit 21 into image light. As a specific configuration of the light modulation device 22, for example, a system using three transmissive or reflective liquid crystal panels (not shown) corresponding to RGB colors can be cited. In this case, the light emitted from the light source unit 21 enters the light modulation device 22 after being separated into R, G, and B color lights by a dichroic mirror or the like. Each color light is modulated by the liquid crystal panel of each color provided in the light modulation device 22, and then the respective color lights are synthesized by the cross dichroic prism and guided to the projection optical system 23. Moreover, it can replace with a liquid crystal panel and can also be set as the structure using a digital mirror device (DMD). In this case, R, G, and B color lights are modulated by the DMD and guided to the projection optical system 23. Further, a configuration may be adopted in which a single liquid crystal panel or DMD and a color wheel are provided, and image light is output by modulating each color light of R, G, and B.

  The liquid crystal panel or DMD included in the light modulation device 22 is generically called an image forming unit. The image forming unit is driven by a light modulation device driving unit 19 to be described later, and changes the light transmittance or reflectance of each pixel arranged in a matrix to form an image.

  The projection optical system 23 includes a projection lens that projects the image light modulated by the light modulation device 22 onto the screen SC. Specifically, the projection lens included in the projection optical system 23 includes a lens group including a plurality of lenses, and includes a focus lens 24 and a zoom lens 25. The projection lens of the projection optical system 23 includes an anamorphic lens 26 that converts the aspect ratio of the image light modulated by the light modulator 22. That is, the focus lens 24, the zoom lens 25, and the anamorphic lens 26 are collectively referred to as a projection lens.

  The projection optical system 23 is provided with a lens adjustment unit 30. The lens adjustment unit 30 includes a lens shift adjustment mechanism 31, a focus adjustment mechanism 32, and a zoom adjustment mechanism 33. The lens shift adjustment mechanism 31, the focus adjustment mechanism 32, and the zoom adjustment mechanism 33 include a lens driving unit (not shown) that moves a lens included in the projection optical system 23 and a detection unit (not shown) that detects the position of the lens. Have. The lens driving unit includes, for example, a power source such as a motor and an actuator, a link mechanism, and the like, and the detection unit detects the position of the lens optically, magnetically, or mechanically.

  The lens shift adjustment mechanism 31 corrects the positional deviation of the projection image projected on the screen SC by shifting the focus lens 24 and the zoom lens 25 perpendicularly to the optical axis. The lens shift adjusting mechanism 31 changes the position of the anamorphic lens 26 to a position overlapping the optical axis of the projection light projected on the screen SC and a position off the optical axis. That is, switching is performed between a state in which the aspect ratio of light projected onto the screen SC is converted by the anamorphic lens 26 and a state in which the aspect ratio is not converted.

  The focus adjustment mechanism 32 drives the focus lens 24 to perform focus adjustment, and the zoom adjustment mechanism 33 drives the zoom lens 25 to realize the zoom magnification set by the control unit 10. Thereby, the zoom adjustment for adjusting the focus adjustment of the projected image on the screen SC and the enlargement / reduction of the projection image is possible.

  The projection optical system 23 includes anamorphic optical components. The anamorphic lens 26 is disposed so as to be shiftable by a lens shift adjustment mechanism 31. The anamorphic lens 26 is guided by the mechanism of the lens shift adjusting mechanism 31 and operates so as to enter and exit on the optical path of the projection optical system 23, that is, on the optical axis of the projection lens.

  The image processing system of the projector 1 is configured around a control unit 10 that controls the entire projector 1 in an integrated manner, and includes a storage unit 11, an input unit 12, an image input unit 15, an image processing unit 16, a frame memory 17, and a light source drive. Unit 18 and a light modulator driving unit 19. Further, the lens shift control unit 34, the focus control unit 35, and the zoom control unit 36 are connected to the control unit 10, and these may be included in the image processing system.

  The storage unit 11 stores data processed by the control unit 10 and a control program executed by the control unit 10. The control unit 10 (adjustment control unit, selection receiving unit) controls each unit of the projector 1 by reading and executing the control program stored in the storage unit 11. The control unit 10 detects the content of the operation performed by the user based on the operation information input from the input unit 12. The control unit 10 controls the image processing unit 16, the light source driving unit 18, the light modulation device driving unit 19, the lens shift control unit 34, the focus control unit 35, and the zoom control unit 36 in accordance with the detected operation, and the screen. Project an image on the SC.

The projector 1 includes an input unit 12 (input unit) that receives a user input operation. The input unit 12 includes a signal receiving unit 13 that detects an operation of the remote controller 50 and an operation unit 14 that detects an operation of the operation panel 55.
The remote controller 50 includes a plurality of input keys 51 and wirelessly transmits an operation signal corresponding to the operated input key 51 to the projector 1 as an infrared wireless signal, for example. The signal receiving unit 13 receives and decodes a radio signal transmitted from the remote controller 50 that operates the projector 1, and specifies the input key 51 operated by the remote controller 50. The signal receiving unit 13 generates operation information indicating the detected input key 51 and outputs the operation information to the control unit 10.
The operation panel 55 is provided, for example, in the main body of the projector 1 and includes a plurality of input keys 56. The operation unit 14 generates operation information indicating the input key 56 operated on the operation panel 55 and outputs the operation information to the control unit 10. Further, the operation unit 14 controls the lighting state of the indicator lamp of the operation panel 55 according to the operation state and the setting state of the projector 1 according to the control of the control unit 10.

  The image input unit 15 performs a scaling process on the image data D1 input from the outside, and outputs the processed image data D2 to the image processing unit 16. Here, the image input unit 15 includes, for example, a DVI (Digital Visual Interface) interface to which a digital video signal is input, a USB interface and a LAN interface, an HDMI connector compliant with the HDMI (registered trademark) standard, and the like. It has an interface having connectors and the like conforming to the DisplayPort (trademark) standard established by the Standards Association.

  The image processing unit 16 acquires the image data D2 output from the image input unit 15 according to the control of the control unit 10. The image processing unit 16 determines the image size and resolution of the image data D2 to be processed, whether it is a still image or a moving image, or an attribute such as a frame rate if it is a moving image. The image processing unit 16 develops an image in the frame memory 17 for each frame, and executes image processing on the image data D2 using the frame memory 17.

  The image processing unit 16 includes an uneven color correction unit 16a, an alignment adjustment unit 16b, an image quality adjustment unit 16c, and an aspect ratio adjustment unit 16d. The color unevenness correction unit 16a corrects the color unevenness in the frame with respect to the image data D2. The alignment adjustment unit 16b adjusts the position of the image that the light modulation device driving unit 19 forms the image data D2 on the image forming unit of the light modulation device 22. For example, in a configuration in which the light modulation device 22 includes three liquid crystal panels as an image forming unit, if there is a slight shift in the optical path from each liquid crystal panel to a prism that combines color lights, the combined image has a color shift. Occur. The alignment adjustment unit 16b performs a process of suppressing the occurrence of color misregistration by shifting the position at which an image is formed on each liquid crystal panel of the light modulation device 22 in accordance with the deviation of the optical path. In addition, when the magnitude of the optical path deviation is smaller than the equivalent of one pixel of the liquid crystal panel, image processing for compensating for the deviation of less than one pixel is executed. The same applies to the case where the light modulation device 22 includes a DMD.

The image quality adjustment unit 16c performs color correction, sharpness correction, and the like on the image data D2.
The aspect ratio adjustment unit 16d determines the aspect ratio of the image data D2, and performs a process of changing the aspect ratio according to the control of the control unit 10. There is no restriction on the processing order of the color unevenness correction unit 16a, the alignment adjustment unit 16b, the image quality adjustment unit 16c, and the aspect ratio adjustment unit 16d included in the image processing unit 16. Processing may be performed in a predetermined order, or the control unit 10 may control the execution order of processing.

The image processing unit 16 performs resolution conversion processing when the resolution of the acquired image data D2 is different from the resolution of the image forming unit of the light modulation device 22. When zooming is instructed by operating the remote controller 50 or the operation panel 55, the image processing unit 16 may perform enlargement / reduction processing according to the control of the control unit 10.
The control unit 10 controls the type of image processing executed by the image processing unit 16, the timing of image processing, the execution order of image processing, the parameters used in the image processing, and the like.
The image processing unit 16 generates an image signal for displaying the processed frame developed in the frame memory 17 and outputs the image signal to the light modulation device driving unit 19. Further, the image processing unit 16 may perform a frame rate conversion process when the frame rate at the time of forming an image on the light modulation device 22 is different from the frame rate of the image data D2.

  The light modulation device driving unit 19 drives the image forming unit provided in the light modulation device 22 according to the image signal output from the image processing unit 16 to draw an image. The light modulator driving unit 19 is, for example, a driver circuit that drives a liquid crystal panel.

The control unit 10 implements the functions of the projection control unit 10a, the adjustment control unit 10b, and the setting control unit 10c by executing the control program stored in the storage unit 11.
The projection control unit 10 a initializes each unit of the projector 1 according to the operation detected by the input unit 12 and controls the image input unit 15, the image processing unit 16, the light source driving unit 18, and the light modulation device driving unit 19. To project an image.

When the projection control unit 10a projects an image, the adjustment control unit 10b controls the lens shift control unit 34, the focus control unit 35, and the zoom control unit 36 according to the setting values stored in the storage unit 11, and performs projection. The position of each lens of the optical system 23 is adjusted.
The adjustment unit of the present invention corresponds to the lens adjustment unit 30, but the lens shift control unit 34, the focus control unit 35, and the zoom control unit 36 may constitute the adjustment unit together with the lens adjustment unit 30. In addition, the adjustment control unit 10 b controls each process of color unevenness correction, alignment adjustment, image quality adjustment, and aspect ratio adjustment performed by the image processing unit 16 in accordance with the setting value stored in the storage unit 11.
The setting control unit 10c performs setting based on a user input for the adjustment of the lens position performed by the adjustment control unit 10b and the adjustment related to the processing performed by the image processing unit 16.

FIG. 2 is an explanatory diagram of the operation of the projector 1 and shows how the image data D1 is adjusted with respect to the aspect ratio. Here, an example is shown in which an image is projected onto a screen SC having an aspect ratio of so-called cinesco (horizontal: vertical = 2.4: 1 or 2.35: 1).
FIG. 2A shows an example of a projected image obtained by projecting an image having an aspect ratio of 16: 9 onto a Sineco screen SC.

  As shown in FIG. 2A, when the aspect ratio of the image data D1 does not match the aspect ratio of the screen SC, the projection image V1 is projected in a size that fits on the screen SC. In this case, a margin V2 is generated on the side of the projection image V1 due to the difference in aspect ratio. In the state of FIG. 2A, the focus lens 24 is adjusted so as to be focused on the screen SC, and the zoom lens 25 is adjusted so that the projection image V1 does not protrude from the screen SC. The upper limit of the projection size of the projection image V1 is a size in which the vertical size (vertical direction) of the projection image V1 matches the vertical size of the screen SC.

By the way, when the aspect ratio of the image data D1 is the same cinesco size as that of the screen SC and the projection lens position of the lens adjustment unit 30 is set to the same position as FIG. The state shown in B) is obtained. In FIG. 2B, an image V4 with an aspect ratio of 2.4: 1 is in the center of an image V1 with an aspect ratio of 16: 9, and the upper and lower margins V3 are expressed in black. When the projection image V4 and the margin area V3 are combined, the projection image V1 shown in FIG. 2A, that is, the image data D1 of 16: 9 is input.
That is, the state of FIG. 2B is a state in which the Sinesco-sized image data D1 is projected as the same data as the image data D1 having an aspect ratio of 16: 9.

  Here, when the lens position of the projection optical system 23 is changed and the position and size of the projected image are adjusted, the projection image V1 is in the state shown in FIG. In the example of FIG. 2C, the upper and lower margin areas V3 are driven out of the screen SC, and an image is projected onto the left and right margins V2, so that the image V4 can be projected to the full screen size.

  For this reason, in the projector 1, it is preferable to adjust the position of the lens of the projection optical system 23 according to the content of the image data D1. Furthermore, it is preferable that the projection lens position can be registered and easily called up.

  With respect to the image of FIG. 2B, the input image V4 is stretched in the vertical direction (FIG. 2D), and the projected image is stretched left and right by bringing the position of the anamorphic lens 26 on the optical axis. Can be projected on the entire surface of the screen SC (FIG. 2E). In the state of FIG. 2D, the position of the zoom lens 25 is the same as that of FIG. 2A, and the zoom magnification is smaller than that of FIG.

  As described above, the projector 1 adjusts the image processing in the image processing unit 16, particularly the processing of the aspect ratio adjustment unit 16d, in accordance with the aspect ratio of the image data D1, and the position of the projection lens of the projection optical system 23. Is preferably adjusted.

For this reason, in the projector 1, settings relating to the lens position can be stored in the storage unit 11.
FIG. 3 is a diagram illustrating a configuration example of the setting value table 11a regarding the lens position and the image adjustment. As shown in FIG. 3, the storage unit 11 stores settings relating to lens positions, for example, in a table format.

The set value table 11a includes information on a plurality of lens positions. In the drawing, the lens positions are indicated by numbers 1, 2,..., But actually, data indicating the positions of the focus lens 24, the zoom lens 25, and the anamorphic lens 26 is included.
The setting value table 11a includes setting information related to an image in association with the lens position. Specifically, it includes data related to color unevenness correction performed by the color unevenness correcting unit 16a and data related to alignment adjustment processing performed by the alignment adjusting unit 16b. Further, it includes data relating to adjustment processing executed by the image quality adjustment unit 16c and data relating to aspect ratio conversion processing executed by the aspect ratio adjustment unit 16d. These data relating to image settings are parameters that determine the processing of each part of the image processing unit 16, and the processing of the image processing unit 16 is uniquely determined based on the data included in the setting value table 11a.

Accordingly, when any one of the lens positions included in the setting value table 11a is selected, a set of data relating to image settings can be specified corresponding to the lens position.
As described above, depending on the position of the focus lens 24 and the zoom lens 25 of the projection optical system 23, the occurrence of color unevenness and color misregistration differs in the projected image projected on the screen SC. Further, if the aspect ratio conversion process of the aspect ratio adjustment unit 16d is performed in accordance with the position of the anamorphic lens 26, in other words, the use state, the distortion of the projected image does not occur.
As described above, the projector 1 corresponds to the projection lens by storing the data for determining the position of the projection lens in the projection optical system 23 and the data for determining the processing performed by the image processing unit 16 in the storage unit 11 in association with each other. The image processing unit 16 can perform the processing.

When the projector 1 executes OSD processing for superimposing an OSD image such as a menu image on image data, the setting value table 11a may include data for defining the contents of the OSD processing. Specifically, the order of processing for superimposing OSD images, the type of OSD image, the necessity of image processing for the OSD image, and the like. The order of processing means that processing for superimposing OSD images is performed before the aspect ratio adjustment unit 16d converts the aspect ratio in the image processing unit 16 or is processed by the image processing unit 16 and written into the frame memory 17. Whether to superimpose the OSD image on the selected image. The OSD image type is data that designates an OSD image to be used when the projector 1 has a plurality of types of OSD image data corresponding to the aspect ratio of the image data D1. The necessity of image processing for an OSD image refers to whether or not the OSD image is processed by the color unevenness correction unit 16a, the alignment adjustment unit 16b, and the image quality adjustment unit 16c.
Furthermore, when the projector 1 performs another type of image processing on the image data D1, data related to the image processing may be included in the setting value table 11a. Further, the setting value table 11 a may include data relating to the luminance of the light source of the light source unit 21 and data relating to the control of the image forming unit of the light modulation device 22. Specifically, the parameters for the light source driving unit 18 to control the light emission of the light source unit 21, the frame rate for driving the image forming unit of the light modulation device 22, the parameters relating to the control of the drawing timing in the image forming unit, etc. is there.

4 to 6 are flowcharts showing the operation of the projector 1.
FIG. 4 shows an operation for setting the lens position in the projector 1.
When the user operates the remote controller 50 or the operation panel 55 to input to instruct the start of setting, and the input unit 12 detects this input, the control unit 10 starts setting (step S11). Based on the operation of the input unit 12, the control unit 10 controls the lens shift control unit 34, the focus control unit 35, and the zoom control unit 36 to adjust the lens position of the projection lens of the projection optical system 23 (step S12). ). In step S12, data specifying the positions of the focus lens 24, the zoom lens 25, and the anamorphic lens 26 may be directly input by operating the remote controller 50 or the operation panel 55. In step S12, the position of the projection lens may be adjusted according to the operation of the input keys 51 and 56 provided on the remote controller 50 or the operation panel 55.

  Next, the control unit 10 determines whether or not to perform setting related to an image (step S13). In step S13, for example, the control unit 10 causes the projection optical system 23 to project a message that prompts the user to input the necessity of setting for the image, and detects and determines the input performed by the user in response to the message. . When the setting relating to the image is not performed (step S13; No), the control unit 10 ends this process. Since the position of the projection lens has been adjusted after the operation of FIG. 4 is completed, an image can be projected. If the projection is temporarily stopped and the operation shown in FIG. 4 is started during the image projection, the operation returns to the image projection after the operation shown in FIG.

  When setting about an image is performed (step S13; Yes), the control unit 10 causes the projection optical system 23 to project (display) an image setting screen (step S14). For example, the control unit 10 reads out screen data stored in the storage unit 11, outputs the data to the image processing unit 16, and causes the light modulation device driving unit 19 to output an image signal for displaying the screen.

  The control unit 10 accepts an operation performed by the user based on the image setting screen. First, the control part 10 receives the input which selects the item to set (step S15). Next, the control part 10 receives the input of the setting content with respect to the selected item (step S16). As for input in steps S15 to S16, data may be directly input as in step S12, or input may be performed by changing the setting by a predetermined amount in accordance with a key operation. In step S15, selection can be performed so that only some of the image setting items that can be set by the projector 1 are set. Specifically, for example, when the position of the anamorphic lens 26 is set, only the operation of the aspect ratio adjustment unit 16d can be set in association with the position of the anamorphic lens 26. Also, for example, in the setting value table 11a of FIG. 3, a setting value P31 related to color unevenness correction associated with the lens position 3 and a setting value P33 related to image quality adjustment are set, and a setting value P32 related to alignment adjustment and a setting value P34 related to an aspect ratio are It can be set not to be set.

  Thereafter, the control unit 10 writes and stores the content input in step S16 in the setting value table 11a of the storage unit 11 (step S17). In step S17, the lens position adjusted in step S12 and the image setting content input in step S16 are written in the setting value table 11a in association with each other.

  Thereafter, the control unit 10 determines whether the setting is completed (step S18). When a setting completion instruction is input by operating the remote controller 50 or the operation panel 55 (step S18; Yes), the control unit 10 ends this process. When the setting is not completed, that is, when an instruction to redo the setting is input by operating the remote controller 50 or the operation panel 55 (step S18; No), the control unit 10 returns to step S12.

FIG. 5 shows an operation for setting the position of the projection lens in accordance with the set value table 11a.
When the user operates the remote controller 50 or the operation panel 55 to input to instruct the start of the position setting of the projection lens, and the input unit 12 detects this input, the control unit 10 starts the setting (step S21).

  The control unit 10 determines whether or not to adjust the position of the projection lens by selecting data in the setting value table 11a (step S22). When selection of data in the setting value table 11a is instructed by user input (step S22; Yes), the control unit 10 displays a lens position selection screen (step S23). On the lens position selection screen displayed here, for example, a list of lens positions included in the setting value table 11a is displayed in a manner that allows a selection operation.

The control unit 10 receives an input for selecting the position of the projection lens by the input unit 12 (step S24), and acquires data of the selected lens position from the setting value table 11a based on the received input (step S25). .
Subsequently, the control unit 10 acquires setting data related to the image included in the setting value table 11a in association with the lens position selected in step S24 (step S26).

  Based on the data acquired in step S25, the control unit 10 controls the lens shift control unit 34, the focus control unit 35, and the zoom control unit 36 to adjust the position of the projection lens of the projection optical system 23 (step S27). . In addition, the control unit 10 controls the image processing unit 16 based on the data acquired in step S26, performs settings related to the image processing executed by the image processing unit 16 (step S28), and ends this processing.

  On the other hand, when an input indicating that the lens position is not selected from the setting value table 11a is received (step S22; No), the control unit 10 determines the lens position of the projection optical system 23 according to the operation of the remote controller 50 or the operation panel 55. Adjust (step S31). The operation in step S31 is the same as that in step S12 (FIG. 4), for example. Thereafter, when an input relating to image quality adjustment is made by operating the remote controller 50 or the operation panel 55, the control unit 10 performs settings relating to image processing based on this input (step S32), and ends this processing.

  Since the position of the projection lens has been adjusted after the operation of FIG. 5 is completed, an image can be projected. Further, when the projection is temporarily stopped and the operation of FIG. 5 is started during image projection, the image projection is resumed after the operation of FIG. 5 is finished.

  As described above, in the projector 1, processing related to an image performed by the image processing unit 16 or the like is set in association with the position of the projection lens of the projection optical system 23, and this setting can be stored in the storage unit 11. Then, by selecting the stored setting, it is possible to adjust the lens position and automatically set the processing by the image processing unit 16 corresponding to the lens position. For this reason, it is possible to easily select and adjust the lens position, and it is possible to perform setting of image processing suitable for the adjusted lens position.

  In addition, when the aspect ratio changes while projecting an image, the projector 1 can set the lens position and the image using the setting value table 11a corresponding to the change in the aspect ratio. This operation is shown in FIG.

  The operation in FIG. 6 is executed in the background after the projection of the image is started (step S41). The control unit 10 causes the image input unit 15 or the image processing unit 16 to detect the aspect ratio of the image data D1 (step S42), and determines whether or not the aspect ratio has been changed (step S43). When it is determined that the aspect ratio has been changed (step S43; Yes), the control unit 10 selects from the setting value table 11a a lens position corresponding to the changed aspect ratio, that is, the aspect ratio detected in step S42. (Step S44).

  The control unit 10 acquires the lens position data selected in step S44 from the set value table 11a (step S45). Further, the control unit 10 acquires setting data related to the image included in the setting value table 11a in association with the lens position selected in step S44 (step S46).

  Based on the data acquired in step S45, the control unit 10 controls the lens shift control unit 34, the focus control unit 35, and the zoom control unit 36 to adjust the position of the projection lens of the projection optical system 23 (step S47). . Further, the control unit 10 controls the image processing unit 16 based on the data acquired in step S46, and performs settings related to image processing executed by the image processing unit 16 (step S48).

The control unit 10 determines whether or not to end the projection (step S49). When it is determined that the projection is to be ended, such as when an instruction to end the projection is given by user input (step S49; Yes), the control unit 10 ends this process. If the projection is not finished (step S49; No), the process returns to step S42.
On the other hand, if it is determined that the aspect ratio of the image or video being projected has not been changed based on the aspect ratio detected in step S42 (step S43; No), the control unit 10 proceeds to step S49.

  For example, there is a case where video content (so-called scenario file) is displayed such that a video including a plurality of frames having different aspect ratios or a plurality of still images having different aspect ratios are switched and sequentially displayed. In such a case, the operation of FIG. 6 allows the projector 1 to always project an image on the screen SC in an appropriate state corresponding to the change in the aspect ratio.

  As described above, the projector 1 according to the embodiment to which the present invention is applied includes the light source unit 21 and the light modulation device 22 that modulates the light emitted from the light source unit 21 into image light based on the image signal. . The projector 1 also includes a projection optical system 23 that includes a projection lens that projects image light, and a lens adjustment unit 30 that adjusts the position of the projection lens. The projector 1 includes an input unit 12 that receives input of the position of the projection lens and settings related to the formation of image light by the light modulation device 22, the position of the projection lens input by the input unit 12, and the formation of image light. And a storage unit 11 for storing the settings. The control unit 10 receives an input for selecting the position of the projection lens stored in the storage unit 11, and adjusts the position of the projection lens in the lens adjustment unit 30 according to the position of the projection lens selected according to the received input. Let it be done. The control unit 10 controls the light modulation device 22 according to the setting relating to the formation of the image light corresponding to the position of the selected projection lens. For this reason, when adjusting the position of the projection lens, the image light can be adjusted corresponding to the position of the projection lens. For this reason, for example, the image quality, the aspect ratio, and the like can be adapted to the position of the projection lens, so that adjustment relating to the image quality corresponding to the position of the projection lens can be easily performed.

Further, the storage unit 11 stores the position of the projection lens and the setting relating to the formation of the image light input from the input unit 12 in association with the position of the projection lens. For this reason, the setting related to the formation of the image light can be easily set by inputting the setting content corresponding to the position of the projection lens.
Further, the storage unit 11 stores the position of the projection lens and the setting relating to the formation of the image light in association with each other by using, for example, the setting value table 11a. For this reason, the setting according to the position of a projection lens is easily realizable about the setting regarding formation of image light. Thereby, the adjustment regarding the image quality corresponding to the position of the projection lens can be easily performed.

  Further, the input unit 12 is configured to be able to input a plurality of setting items related to the formation of image light by the light modulation device 22, and can select setting items to be input by the input unit 12. For this reason, arbitrary items can be set regarding the formation of image light.

  The light modulation device 22 has a configuration in which an image is formed on the image forming unit based on the image signal, and the light emitted from the light source unit 21 is modulated by the formed image. The settings relating to the formation of image light by the light modulation device 22 include the aspect ratio of the image formed by the light modulation device 22, the alignment adjustment value for adjusting the image formation position, and the color unevenness adjustment value of the image formed by the light modulation device 22. Any of image quality setting values of the image formed by the light modulation device 22 is included. Therefore, the image aspect ratio, alignment adjustment value, color unevenness adjustment value, image quality setting value, and the like can be appropriately adjusted in accordance with the position of the projection lens.

  The above-described embodiment is merely an example of a specific mode to which the present invention is applied, and the present invention is not limited. The present invention can be applied as a mode different from the above-described embodiment. For example, in the above embodiment, the configuration in which the projection optical system 23 includes the focus lens 24, the zoom lens 25, and the anamorphic lens 26 has been described, but the present invention is not limited to this. One or a plurality of lenses included in the projection optical system 23 may serve as the focus lens 24 and the zoom lens 25, or the projection optical system 23 may not include the zoom lens 25. Accordingly, the projection optical system 23 may be configured to include at least one movable lens.

  In the present embodiment, the position of the anamorphic lens 26 can be input, but the present invention is not limited to this. For example, when there are a plurality of projection modes in which the projector 1 displays an image (video) and the use of the anamorphic lens 26 is set in association with any one of the projection modes, the designation of the projection mode is performed by specifying the position of the anamorphic lens 26. You may accept as designation of. For example, the projector 1 has a projection mode such as a theater mode in which the aspect ratio is converted by the anamorphic lens 26 and a normal mode in which the projection is performed without using the anamorphic lens 26, and each projection mode and the aspect ratio are associated with each other. is there. In this case, the projection mode may be switched (set) by selecting the projection mode from the setting menu screen, and the use / non-use of the anamorphic lens 26 may be automatically switched. Further, in step S43 in FIG. 6, the projection mode may be switched as an aspect ratio change.

  Further, in the present embodiment, the projector 1 has been described by taking as an example the case where the screen displayed in FIGS. 4 to 5 such as the setting menu screen for setting the aspect ratio is displayed with the OSD image superimposed thereon. . The present invention is not limited to this. For example, in a liquid crystal panel (not shown) provided in the light modulation device 22, an image region corresponding to a portion where an input image is not formed (for example, in FIGS. 2D and 2E). A setting screen may be displayed in the non-display area V3). Alternatively, the input image formed on the liquid crystal panel (not shown) may be reduced to create a portion corresponding to the non-display area V3, and a setting screen or the like may be displayed on this portion.

  In the above embodiment, the projector 1 has been described by taking as an example the configuration in which the projector 1 projects an image based on the image data D1 supplied from an external device, but the present invention is not limited to this. Of course, the projector 1 may be configured to project a video or an image based on image data stored in the storage unit 11, another storage device, or a portable storage medium.

  Moreover, each function part shown in FIG. 1 shows the functional structure of the projector 1, Comprising: A specific mounting form in particular is not restrict | limited. In other words, it is not always necessary to individually implement hardware corresponding to each functional unit, and it is of course possible to implement a configuration in which the functions of some functional units are realized by software by the processor executing a program. There are other detailed configurations that can be arbitrarily changed.

  DESCRIPTION OF SYMBOLS 1 ... Projector, 10 ... Control part (selection reception part, adjustment control part), 10a ... Projection control part, 10b ... Adjustment control part, 10c ... Setting control part, 11 ... Memory | storage part, 11a ... Setting value table, 12 ... Input 16, image processing unit, 16a ... color unevenness correction unit, 16b ... alignment adjustment unit, 16c ... image quality adjustment unit, 16d ... aspect ratio adjustment unit, 20 ... projection unit, 21 ... light source unit, 22 ... light modulation device ( Modulation unit), 23 ... projection optical system, 24 ... focus lens (projection lens), 25 ... zoom lens (projection lens), 26 ... anamorphic lens (projection lens), 30 ... lens adjustment unit (adjustment unit), 31 ... lens Shift adjustment mechanism, 32 ... focus adjustment mechanism, 33 ... zoom adjustment mechanism, 34 ... lens shift control unit, 35 ... focus control unit, 36 ... zoom control unit, 50 ... remote control 55 ... operation panel, SC ... screen.

Claims (7)

A light source;
A modulator that modulates light emitted from the light source into image light based on an image signal;
A projection lens for projecting the image light;
An adjustment unit for adjusting the position of the projection lens;
An input unit that receives an input of a setting relating to the position of the projection lens and the formation of the image light by the modulation unit;
A storage unit for storing the position of the projection lens input by the input unit and the setting relating to the formation of the image light;
A selection receiving unit that receives an input for selecting the position of the projection lens stored in the storage unit;
The image light corresponding to the position of the projection lens selected by causing the adjustment unit to adjust the position of the projection lens according to the position of the projection lens selected according to the input received by the selection reception unit. An adjustment control unit for controlling the modulation unit according to the setting relating to the formation of
A projector comprising: The storage unit stores the position of the projection lens and the setting relating to the formation of the image light input by the input unit in association with the position of the projection lens;
The projector according to claim 1. The storage unit stores the position of the projection lens and the setting relating to the formation of the image light in association with each other;
The projector according to claim 1 or 2. The input unit is configured to be able to input a plurality of setting items related to the formation of the image light by the modulation unit,
Being able to select the setting item to be input by the input unit;
The projector according to claim 1, wherein: The modulation unit has a configuration that forms an image based on the image signal, and modulates light emitted from the light source by the formed image,
The setting relating to the formation of the image light by the modulation unit includes the aspect ratio of the image formed by the modulation unit, the alignment adjustment value for adjusting the formation position of the image, the color unevenness adjustment value of the image formed by the modulation unit, Including any of image quality setting values of an image formed by the modulation unit;
The projector according to claim 1, wherein: The adjustment unit performs at least one of zoom adjustment by the projection lens and shift adjustment of the projection lens;
The projector according to claim 1, wherein: In a control method for a projector that modulates light emitted from a light source into image light based on an image signal and projects the image light,
Accepts input of the position of the projection lens and the setting relating to the formation of the image light,
Storing the input position of the projection lens and the setting relating to the formation of the image light;
Receiving an input for selecting the stored position of the projection lens;
The position of the projection lens is adjusted according to the position of the projection lens selected according to the received input, and the position of the image light according to the setting relating to the formation of the image light corresponding to the position of the projection lens selected. Controlling the formation,
A projector control method characterized by the above.

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